Automatic control of gas for high and low temperature in sequence



Jan. 26, 1965 B c. DOUGLAS AUTOMATIC CONTROL OF GAS FOR HIGH AND LOW TEMPERATURE IN SEQUENCE Filed Aug. 16, 1962 2 Sheets-Sheet 1 FIGJ.

Jan. 26, 1965 B. c. DOUGLAS 3,167,248

AUTOMATIC CONTROL OF GAS FOR HIGH AND LOW TEMPERATURE IN SEQUENCE 2 Sheets-Sheet 2 Filed Aug. 16, 1962 United States Patent O 3,167,248 AUTGMATIC CNTROL F GAS FUR HIGH AND LOW TEMPERATURE 1N SEQUENCE Bradley C. Douglas, Kirkwood, Mo., assigner, by mesne assignments, to Micro Controls, Inc., St. Louis, M0., a

corporation of Missouri Filed Aug. 16, 1952, Ser. No. 217,375 14 Claims. (Cl. 236-15) This invention relates to a gas regulating system and to apparatus constituting such a system, and with regard to certain more specific features, to a regulating system for cooking ranges and the like. The invention is an improvement upon structures of the general class shown in my U.S. patent application Serial No. 177,512, tiled March 5, k1962, for Gas Regulating Apparatus, matured sPatent No. 3,123,299.

Among the several objects of the invention may be noted the provision of a gas regulating system and apparatus'which willV program a gas heating cycle wherein accurate regulation is obtained throughout both lowand high-temperature ranges according to various desired sequences, wherein the low range is useful, for example, for food warming, defrosting and the like; the provision of apparatus of the class described wherein a wide variety f of sequences may be obtained in the succession of lowand high-range control; the provision of apparatus of the class described adapted to provide sequences in which action in a low-temperature range may occur before action in a high-temperature range, or vice versa, and one in which actions in a low-temperature range may precede and Succeed action in a high-temperature range; and the provision yof such apparatus which accomplishes regulation over hghand low-temperature ranges by means of comparative low-cost parts and in an economical manner. Other objects and features will be in part apparent and in part pointed out hereinafter.

The invention accordingly comprises the constructions hereinafter described, the scope of the invention being indicated in the following claims.

In the accompanying drawings, in which one of various possible embodiments of the invention is illustrated,

FIG. l is a View diagrammatically illustrating the invention;

FIG. 2 is a front View in elevation of a thermostatic control valve embodied in the apparatus of FIG. l;

FIG. 3 is an axial section of the valve shown in FIG. 2, the section being taken on line 33 of FIG. 2, some parts being omitted for clarity; and

FIG. 4 is an enlarged fragmentary section taken on line 4-4 of FIG. 3.

Corresponding reference characters indicate corresponding parts throughout the several views of the drawings.

Although the invention described herein has general use, a particular use is for thermostatic gas valve systems for oven temperature control, in relation to which an oven will be described as an example.

The gas regulating apparatus is shown generally in FIG.

' 1. In this ligure, the -oven chamber of a gas range is generally indicated at A. P1 is a constantly burning pilot burner adapted to receive a small amount of gas from a main gas supply line M over a low-liow line W. An

adjustable low-flow limit valve LP in line W controls the amount of gas passing to pilot burner P1. Pilot burner P1 serves to ignite an loven burner B when gas is supplied to the latter in a manner hereinafter described.

A normally extinguished pilot burner P2 is connected to a thermostatic gas valve 1 by a line R. The thermostatic gas valve 1 and main gas supply line M are connected together by a line K. As will be made apparent, the iiow of gas to pilot burner P2 is controlled by the op- ICC eration of the valve 1, which in turn is under the control of a manually operated dial D (FIG. 2) and a fluid-lled temperature-responsive bulb Z. Dial D is provided with markings from F. to BROIL, the latter being approximately 600 F. (FIG. 2). Bulb Z is located in the space to be heated as, that is, the oven A which is heated by burner B. v

Gas is supplied to burner B from line M through a line C and an electrically operated main burner valve V which opens when electrically excited. An adjustable main-how limit valve LB controls the maximum amount of gas that may pass through line C to burner B.

The control apparatus includes an electrical circuit comprising a pair of power lines L1 and L2 connected between an electrical power source and a transformer T, the latter being connected to one terminal of valve V by a line S. The other terminal of valve V is connected to one terminal of a ame switch F by a line I. The other terminal of flame switch F is connected to one terminal of a thermostatic switch Y by a line X. Closing of the iiame switch F is effected by heating from the flame of a pilot burner P2. Switch Y, which is located in the space heated by main burner B and therefore is in heat-exchange relationship with the latter, is adapted to be closed when the temperature of a flame emitted by the main burner is below 140 F., for example. Above such a temperature, the switch Y will be open.

Switch Y is connected to transformer T by a line G having a manually operable switch H therein. A timing device Q includes two switches 3 and 5. Switch 3 is shunted across switch Y by lines 7 and 9. Switch 5 is shunted across switch H by lines 11 and 13.

Gas issuing from pilot P2 will be ignited by the flame issuing from the constantly burning pilot P1. Flame switch F is so located that it will be heated to its predetermined operating temperature only by a ame issuing from pilot burner P2, and not by the llame issuing from pilot burner P1. Thus the electrically operated valve V will be energized, i.e., opened, when the ame switch F is closed, and the remaining circuit to the transformer is closed through one of the following switch paths: Y and 5; Y and H; 3 and 5; 3 and H. Timer Q controls the opening and closing of the switches 3 and 5. Further details concerning the timer Q are not necessary to this description inasmuch as a variety of timers are commercially available which by suitable indicated settings will set cams to operate numbers of switches in any order for various times. The operation of the switches Y, 3, 5, and H will be made apparent hereinafter.

Referring now to FIGS. 2 and 3, valve 1 comprises a body 15 formed of parts 17 and 19 held together by screws 2l. At numeral 23 is shown a gas inlet into which an inlet tting 25 is threaded. Inlet fitting 25 connects inlet 23 with the main gas line M through the pipe K (FIG. l). Parts 17 and 19 form a gas chamber 27 which is connected to inlet 23 by an inlet passage 29. An outlet port 31 is connected by a fitting 33 to line R (FIG. 1).

Body 15 is provided with a passage 35 extending through the body to the gas chamber 27. lThe inner end of this passage 35 is threaded as indicated at 37. Passage 35 is in communication with outlet port 31 by means of a port 39. An adjustable threaded control valve 41 is adapted to control the maximum amount of gas that may pass through port 39. Threaded within passage 35 is a rotatable tubular member 43. Tubular member 43 is provided with an annular groove 47 on both sides of which are located sealing rings 49 which seal member 43 within passage 35. Member 43 is provided with a central passage 51 which is threaded as indicated at 53. A port 55 connects passage 51 with annular groove 47.

Threaded into passage 51 is a rotatable stern 57 which has a screwdriver control slot 59 on its outer end for adjustment purposes. A resilientsealing'ring 61 toward the outer` end .of stem 57 seals the stem within passage 51. VAn annular groove 63 is provided in stem 57 between 'its inner and outer ends andisalignedWithpOrt 55.'A 1

VStern 57- is provided-with a central lcavity 65.opening y at the inner end-thereof intov gas-chamberZ. Y Openings .67 connect cavity 65 with annular Ygroove 63.V The inner endof stem 57 is provided .with a seat 69 arounda hexagonal enlargement 66 of cavity 65 to receive an Allenhead wrench forV initially adjusting the position of seat 69 `relative to tubular member 43'. AThus the location of seat 69 can be `adjusted with awrench from the'inner end ofthe stem `57701` with a screwriver from the (outer` end of the stem.

- A more or less square valve V1nennber'71 is adapted'to seat on seat 69 and is ybiased therefrom .byva spring `'7-3.4 The operating engagement between Valve member 71 and spring 73 willV be clear from FIG. 4. Surrounding the valve member71 and spring 73 isa cage v1nember75 y slotted to provide passagesand spring ngers 77 (FIG. 4), thereby also forming a press iit .Within the innerend of ,member'tn Valve rnember71v is coniined in Vvcagefmemfber'75.'V Cage member 75 also includes a' sleeveV 79 eX- tending into chamber 27. Gas lmay owbetween the fngers77. .y A double-walled cup Slis located inl chamber 271'V Cup V8.1 hasY an inside wall 83 and an outsidewall 85,-the'latter` being cent-rally soldered Vor otherwise'l vattached tofthe inside ofpart-j19. The marginal portions'87 ofthe WallsV 83 andV 85 'are sealed-together. as by welding or soldering,

with/an opening 91 communicating with the line U. The other end of line U-is lconnected -to bulb -Z which,as previously stated, is Alocated inthe space vto be heated by the burner B." The-bulb Z, line U .and available spaceV between the -bimetallic members S3 andSSl are filled witha.,Y f

thermally responsive liquid which is adapted vuponfexpansion in response to heatingto enter'between the members 83and 85, so as to lforce them apart. This drives `the remaining portions of the walls being unjoined.Y Both 1 .I walls are corrugated in their portions forming the inside -bottom89 of cup vS1; Theoutside wall 85 is providedprevented fromv turning untilthe member 101 (on which the dial is located) is pushed inwardly. to release the Y finger 1.11 from notch 113. VA stop 115 located on the inside of cup 99 prevents thefdial'D and member 101 from counterclockwise rotation-as viewed in-FIG. 2 beyond the point marked BROILn n. Y

Any ofvari'ous types of 4electric eontrolclocks or mechanisms can be utilized and can fbe set to open and close y switches 3.1and Sl at various times, depending on the desired sequence of heating cycles; or the operation of switchesand f5 may. Abe Ar'nanually.effected. Thus, the heating cycles can beprogrammedor sequenced-as desired. The following exampleY illustrates one mode of operation vof. a typical heating program. It willibe assumed thatthe "thermostatic switchY -is calibratedv to remain closed for temperatures below 140 F. and. to open on temperatures above 140 F.; also that switch H is open as shown.

' 'Consider a situation wherein a woman'wishes to cook a kroast for ltwo hours Vat 500 F. and thatshe will'be absent for vehou'rs.: f Assume she ispl-anning to rleave the house at noon andwishes the. roast' to bef done at 4:00pm. although" she may notreturn to her house 5 maint'ain'ed'inl a closedposition vand switrchwS yopened at 4:00 The `purpose of thefropen'ing and closing-of these'pswitche's will become apparent as hereinafter eX- plained. The dial D isturnedcounterclockwisezto bring the 500 F. 'mark to the Ltop Vof thedial. may'then'leave the house-at ythis time. v

When Vthe dia'l is'turned to 500 .F.,zthe member 43 The woman vandconseq'uentlyV seat 69 -are moveda predetermined 'amount to 7the` left as .viewed in FIG..3.' Spring 73 maintainsvalve member'v 71 4against "pin95 so Athat gas .passes i "from the-chamber 275 through-the cage `member 75.. into the bottom member 33 .to the left'as viewed inFIGL 3 away from bottom 85. A

The inner bottom S3'carr1es an. attached,. -cup-Shaped Y l member-.93 which has a sliding engagement'for"vrtrael on a flangedjpin 95. Pin 95 .and guide member 93 are held together as a unit byy an'expansible spring 96 located pin 95.' `Washer 97 is heldzinjplaceonpin 95 Vby a .retaining ring 98. When the dial D is in an OFF-position and the oven is at room temperature pin 9 5 holds valve member 71 against seat 69. When the dial D is turned on,

left as viewed in-FG. 3 and gasflows through valve to outletl 3L Y In response to increased oven temperatures-applied to bulb Z, the uid in the bulb and line'Vv presses to the left'V the following parts: the inside cup bottom83, parts 93,

96; 97, 98, 95-and valve member 71. This ltends to seat valve 71 on seat 69. Under 'conditions in which the valve jbetweenpguide member 93 anda washer 97 surrounding i i.e., counterclockwise as Vviewed in FIG. 2, the member 1 43, stem STandy consequently seat 69. are movedto. theV the hollow .portion of stem57. The gasiflows through port 67, groove 63,;port 55, groove V'47, port 39, out1e'tf'31 and line `R`tovthe normally vextinguished pilot burner. P2

' where it is ignited by constantly burning pilot B1.' The flame switchvF is heated to lits predeterminedoperating temperature land closes. Switch Y Iis ina closed position as the oventem'perature at this time is at room tempera- '-ture, which is .substantially below 140 F; However,

since both switch 5 -and switch 3 are open, a circuit through the' electrically 'operated' valve fV. fis not. completed and consequentlymvalve ll'remainsfclosed.

At 2:O0-p'.m.,'the 'switches' 3 and 5 become closed. A

'- circuit'through the valve. V isthen completed .and the valve is opened. Gas is thenv supplied to the main pilot YB where'it is-Y ignited by' the flame `from pilotPl. It is to be noted that initially current will flow through both switch 3 `and"switcl1 YA 'to Vcomplete the circuit through Y .closed switch f5. However, as the temperature rises -above 140 F., switch Y opens and the current'flows only 71 may have closedand further expansion of the fluidVv occurs, member 93 will slide with .overtravelo'n pinl95'. Thus an overriding" actionroccurs which prevents damage toanyparts. Upon cooling, the reverse action occursas the valve 71 moves toward its open position..

Mounted on the rear side -of member 17, '.e.,-the left side as viewed in FIG. r3, lis a cap-member 99. An oper s ating or control member 101. passes throughcap 99 and issplined as indicatedat 103 to member 43. VA" WasherV 105 is biased against ian annularshoulden107 on member 101 by an expansiblespring 109. Thus theinember 101 y is biasedto the left. Washer105 has afingerll'll which 'engages in Va notch 113 in cap. 99 when Vthe VdialfD and rmember 101 are in an `OFF position... The dial is vthusV B1 VVmaintains the 'through' switch 3Q As. the temperature reaches v500'.r F., thecup bottomwall 83 is pushedto the left as viewed in FIG. 3vand the parts 93,."96, 9.7,98k and"pini95 cause thefvalve 71 to 'seatonseat-69 therebystopping' the iiow of gasfthrough'the valve 1. This causes'pilot P2 to. be Yextinguished'and-llame switch F'cools rapidly. Upon K cooling. to -its-predetermii'ied*operatingV temperature, flame switch F'open's, thus interrupting'the circuit through the main-flow valve V Yand causing the Vlatter to close.Y `As the oven begins to cool, the valve memberv 71 lmoves to the right .as viewedin'FIGyS and permits gas :to ow v Anited and heats vthejilame.svt/.itch'"Fto its operating `ternperatur'e,'fat.which, timethe. amefswitch Fcloses and through the valve 1 to pilot P2 .which again becomes igvalve Vi's opened. "ThisL intermittent gasjow to. burner 'oven temperature at. approximately At 4:00 p.m., switch 3 is opened, and switch 5 remains closed. Since the thermostatic switch Y is open (the temperature being above approximately 140 F.), the circuit through the main-How valve V is interrupted and the Valve closes. The temperature in the oven decreases towards 140 F. During this time, lame switch F is maintained closed since gas is supplied through valve 1 to pilot burner P2. This is because the dial D is set at 500 F. causing seat 69 to remain in its backed-olf position, while the thermally responsive liquid in bulb Z, line U and between cup members 83, 85 contracts and permits spring 73 to force valve member 71 to the right as viewed in FIG. 3 off of seat 69. When the temperature decreases to approximately 140 F., thermostatic switch Y closes thereby closing a circuit through valve V and opening the latter to permit gas to ow to the main burner B. The temperature then increases slightly above 140 F. and switch Y opens, interrupting the circuit through valve V and causing the latter to close. The temperature is then maintained at approximately 140 F. .under the control of thermostatic switch Y until the woman turns the dial to the OFF position.

It will be seen that the operation of the main burner is controlled by the llame switch F during high-temperature operation, and that the total length of the hightemperature period is controlled by switch 3, while switch Y controls the operation of the main burner during the low-temperature period.

The switch 5, being initially open, prevents the oven from attaining a temperature of approximately 140 F. immediately after the dial D is turned to the 500 F. mark since switch Y is initially closed and would close the circuit through valve V if switch 5 were closed. In this regard, it will be understood that the switch 5 and lines 11 and 13 could be eliminated and the switch H closed (or replaced by a length of wire) if it were desired I,to have the oven attain a temperature of approximately 140 F. immediately upon turning the dial D to its high temperature setting. The mode of operation after a period at 140 F. is then the same as described above, i.e., when it is desired to raise the temperature to approximately 500 F., switch 3 is closed. After a predetermined period at 500 F., switch 3 is opened and the oven temperature drops to approximately 140 F., where it is maintained under control of switch Y until the dial D is turned to an OFF position.

It is to be understood that Various other cooking cycles could be programmed by setting the switches 3, 5 and H to open and close at various times.

Although two pilot burners are shown, i.e., a constantly burning pilot P1 and a normally extinguished pilot burner P2, it will be understood that a single pilot burner could be utilized in an equivalent manner. Such a pilot burner would have a constant low llame of insuiiicient intensity to heat llame switch F to its predetermined operating temperature but when supplied with an additional amount of gas through valve 1, would produce a flame of greater intensity than the normally low-intensity llame and cause llame switch F to be heated to its operating temperature. When this additional gas to the pilot burner is cut oli, the pilot flame drops back to its normal low intensity and ilame switch F cools to below its predetermined operating temperature. Whether the apparatus has a twoburner pilot system or a one-burner pilot system it will be readily visualized that there will be a constant low-intensity tiame emitted from the pilot means (from P1 in the pilot system shown in the drawings and from an equivalent single pilot burner as described). Also, in either case a high intensity llame will be emitted from the pilot means when an extra amount of gas is supplied thereto through valve 1 (to P2 in the system shown or to the equivalent single pilot mentioned) In view of the above, it will be seen that the several objects of the invention are achieved and other advantageous results attained.

As various changes could be made in the above constructions without departing from the scope of the invention, it is intended that all matter contained in the above description or shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.

What is claimed is:

1. A gas regulating system comprising means forming a chamber, means for controlling the heating of the chamber throughout lowand high-temperature ranges comprising constantly burning pilot burner means having a low intensity llame normally issuing therefrom, a main burner located in said chamber adapted to be ignited from said pilot burner means, a main-How control valve controlling gas flow to the main burner, an electrical control circuit comprising a source of electrical energy, electrically operated means adapted to control the operation of said valve, a I'irst thermostatically operated switch movable between first and second positions and adapted to move to the second position in response to the temperature produced by a pilot flame of a greater intensity than the temperature produced by the low-intensity pilot flame, a second thermostatic switch located in heat-exchange relationship with said main burner and movable between first and second positions, said second thermostatic switch being in its second position when the temperature within said chamber produced by a llame emitted from the main burner is in said low range, said second switch being movable to its lirst position when the temperature produced by a llame emitted from the main burner rises yabove a predetermined value toward said high-temperature range, and a third switch movable between first and second positions, said third switch normally being in its rst position, said main-iiow control valve being opened by said electrically operated means when said rst switch is in its second position and at least one of the remaining switches is in its second position.

2. A gas regulating system as set forth in claim 1 wherein said circuit includes a fourth switch adapted for movement between first and second positions, said mainilow control valve being opened when said rst and fourth switches are in their second position and one of the remaining switches is in its second position.

3. A gas regulating system as set forth in claim 1 including a valve body having an inlet adapted to be connected to a source of gas and an outlet connected to said pilot burner means, a thermostatically controlled valve member controlling gas flow from the inlet to the outlet, and adjustable control means for varying the temperature in said chamber at which the valve member will block the gas flow from the inlet to the outlet, said pilot burner means being adapted to produce a pilot llame of suiicient intensity to move said rst switch to its second position upon receiving suiiicient gas from said outlet.

4. A gas regulating system as set forth in claim 3 wherein said circuit includes a fourth switch adapted for movement between first and second positions, said mainllow control valve being opened when said first and fourth switches are in their second position and one of the rcmaining switches is in its second position.

5. A gas regulating system as set forth in claim 1 wherein said iirst switch comprises a flame switch located in heat-exchange relationship with said pilot burner means.

6. A gas regulating system as set forth in claim 5 including a fourth switch connected in series with said electrically operated means, flame switch and thermostatic switch, said main-flow control valve being opened when said llame switch and said fourth switch are closed and one of the remaining switches is closed.

7. A gas regulating system comprising means forming a chamber, means for controlling the heating of the chamber throughout lowand high-temperature ranges cornprising constantly burning pilot burner means having a low-intensity ame normally issuing therefrom, a main burner located in said chamber adapted to be ignited from said pilot burner means, a main-flow control valve conswitches isY closed; l

'trolling gas flow vto the main burner,` anrelectrical control circuit comprisinga source .of electrical energy, electrically operated meansadapted'upon energization'toopen said vvalve and upon deener'gization tov closeV said valve, a rst thermostatic switchwadaptedto close in responserto the temperature produced by a` pilot flame of a greater intensity than the temperature. produced by" thelow-intensity pilot flame, a second thermostatic switch located in heat-exchange,relationship withl said main burner, said second thermostatici switch being closed when the'tempe'rature rangea third switch shunted acrosssaid secondy therfrom the maink burner is in saidlow rrange, said'second switch being adapted to be open when the temperature i tricallyo'perated means adapted upon energization to open said .valve,.;a first thermostatic switch adapted to be f vclosed upon heating and located in heat-exchange Yrelaproduced by a flame emitted from the main burner-rises.v

above a predetermined value toward said high-temperaoutlet, and adjustable control means for varying the tem- -15 ture range, a third switch shunted across said second .ther- Y mostatic switch,a valve. b'odyhaving an inlet adapted toY be connected to a source of gas' and an outlet connected to the pilotA burner means, a lthermostatically controlled 4valve member controlling *gasV ow from the inlet to the perature in said chamber at which the valve member will Y block the gas fiow .from 'the inlet to theA outlet, said pilot tionship with saidv main pilot burner, a Vsecond,V thermostatic, switch 'locatedgin heat-exchange 'relationship with said main burner, saidsecond switch adapted to be closed when the temperature Vwithin'said chamber produced by a flame emitted from the main burner is in said low range,

vsaidY second switch being opened whenpthe temperature produced by a flame emitted'from the vrnain burner rises above a predetermined temperature toward said vhightemperature range, and a third switch shunted across said .second switch, a` Valve, body having anv inlet adapted to be-connected-to va source ,of gas and an outlet connected Vto 'the main pilot burner, a thermostatically controlled Y Valve memberr controlling gas Vfiow from the inlet to the ,.outletv, and adjustable ,controly means for varying the `temperature in said chamber at which the valve member ywill block the gasrflow from the inlet to the outlet, said Y main pilot burnerbeingV adapted to produce Va pilot flame of sufiicient intensity to move said first switch toits second position upon receiving sufiicient gas from said outlet,` saidfelectrically-operated means, first switchand secburner means being adapted-to produce a pilot flame ofV sufiicient intensity to move said first switchztvo-its vsecondV position upon receiving sufficient gasfroml said outlet,

Vsaidelectrically operated means, first vswitch and second switch beingconnecte'd together in'series across saidy source of power, whereby said main-flow valve is opened when said first switch is closed and one ofthe remaining .rond switch being connected together in series across said source of power, whereby said main-flow .control valve is y,openedv'vh'en said rst switch is Yclosed and one` of the remaining switches is closed.V v Y. y l2. A gas regulating system as set forth in claim 1l including, a. fourth switchY` connected inL series with said 8. A gas regulatingY system as set-'forth in claim 7 including a fourth switch'connected in series with said valve, firstjswitch and second switch,vwhereby said main- `flow control valveris'opened when` said first and fourthswitches are closed and one of the remaining switches closed. 1

9. A gas regulating syst-em asset forth in claim V7 wherein said first switch'cornprises ka flame switch located .Y

inVv heat-exchange .relationship with. said pilot burner means.

10. A gasregulating systemafs -s'et forth infclaim 9 including a fourth switch connected in series .Withfsaid valve, name switch and second switch,` Vwherebyfsaid main-V.V

fiow control valve is opened whenY said flame switchl and:V Y

said fourthswitch aregclosedand one of theremaining switches is closed. Y Y

1l. A gas regulatingsystem comprising means'vfor'nlingy Y a chamber, means yfor controlling the'kheatingofthe chamber throughout lowandhigh-temperature ranges' comprising a main burner located in said chamber',Y a'

main pilot burner Vadjacent thereto, Vgas supply means,` a

constantly burning auxiliary pilotlburner connected to j said gas supply means adapted to.` light-said main pilot burner and saidV main burner, a main-flow control valve controllingv gas flow to the mainburner, an-electrical cor1-k trol circuit comprising a sourceV of electrical powerele'cand said kfourth switch are closed ing switchesrisclosed.

valve, first switchV and second switch, whereby saidv mainflow `control 'valve isopened when said firstY and fourth switches areclosed and one ofthe remainingy switches is closed..V y Y 13.' AI gas regulating system as setN forth in claim 11 wherein said first switchcornprises a flame switch located inherit-exchange relationship; with said pilot burnermeans;

14.. A gas regulating system as set forth in claim 13 including ,a fourth switch connected in series with said valve, flame switch Vandsecond switch, whereby .said

main-flow control valve is openedA whensaid flame switch andone of theremain-Y References' Cited in'lth'efile of this :patent France 2---- May Y23, 19.60

Patent No. 3,167,248

January 26, 1965 Bradley C. Douglas It is hereby cert' ent requiring oorrecti corrected below.

Column 7, line ll, for "range, across said second ther" read -e wi a third switch shunted by a flame emitted thin said chamber produced Signed and sealed this 6th day of July 1965.

(SEAL) Attest.-

ERNEST W. SWIDER EDWARD J. BRENNER A i testing Officer Commissioner of Patents 

1. A GAS REGULATING SYSTEM COMPRISING MEANS FORMING A CHAMBER, MEANS FOR CONTROLLING THE HEATING OF THE CHAMBER THROUGHOUT LOW-AND HIGH-TEMPERATURE RANGES COMPRISING CONSTANTLY BURNING PILOT BURNER MEANS HAVING A LOW INTENSITY FLAME NORMALLY ISSUING THEREFROM, A MAIN BURNER LOCATED IN SAID CHAMBER ADAPTED TO BE IGNITED FROM SAID PILOT BURNER MEANS , A MAIN-FLOW CONTROL VALVE CONTROLLING GAS FLOW TO THE MAIN BURNER, AN ELECTRICAL CONTROL CIRCUIT COMPRISING A SOURCE OF ELECTRICAL ENERGY, ELECTRICALLY OPERATED MEANS ADAPTED TO CONTROL THE OPERATION OF SAID VALVE, A FIRST THERMOSTATICALLY OPERATED SWITCH MOVABLE BETWEEN FIRST AND SECOND POSITIONS AND ADAPTED TO MOVE TO THE SECOND POSITION IN RESPONSE TO THE TEMPERATURE PRODUCED BY A PILOT FLAME OF A GREATER INTENSITY THAN THE TEMPERATURE PRODUCED BY THE LOW-INTENSITY PILOT FLAME, A SECOND THERMOSTATIC SWITCH LOCATED IN HEAT-EXCHANGE RELATIONSHIP WITH SAID MAIN BURNER AND MOVABLE BETWEEN FIRST AND SECOND POSITIONS, SAID SECOND THERMOSTATIC SWITCH BEING IN ITS SECOND POSITION WHEN THE TEMPERATURE WITHIN SAID CHAMBER PRODUCED BY A FLAME EMITTED FROM THE MAIN BURNER IS IN SAID LOW RANGE, SAID SECOND SWITCH BEING MOVABLE TO ITS FIRST POSITION WHEN THE TEMPERATURE PRODUCED BY A FLAME EMITTED FROM THE MAIN BURNER RISES ABOVE A PREDETERMINED VALUE TOWARD SAID HIGH-TEMPERATURE RANGE, AND A THIRD SWITCH MOVABLE BETWEEN FIRST AND SECOND POSITIONS, SAID THIRD SWITCH NORMALLY BEING IN ITS FIRST POSITION, SAID MAIN-FLOW CONTROL VALVE BEING OPENED BY SAID ELECTRICALLY OPERATED MEANS WHEN SAID FIRST SWITCH IS IN ITS SECOND POSITION AND AT LEAST ONE OF THE REMAINING SWITCHES IS IN ITS SECOND POSITION. 